def run_simulation(fname="tdem_gs_half.h5",
sigma_block=0.01,
sigma_halfspace=0.01):
from SimPEG.electromagnetics import time_domain as tdem
from SimPEG.electromagnetics.utils import waveform_utils
from SimPEG.EM import Analytics, mu_0
import numpy as np
from SimPEG import maps, utils, EM, Survey
from pymatsolver import Pardiso
cs = 20
ncx, ncy, ncz = 20, 20, 20
npad = 10
hx = [(cs, npad, -1.5), (cs, ncx), (cs, npad, 1.5)]
hy = [(cs, npad, -1.5), (cs, ncy), (cs, npad, 1.5)]
hz = [(cs, npad, -1.5), (cs, ncz), (cs, npad, 1.5)]
mesh = TensorMesh([hx, hy, hz], "CCC")
sigma = np.ones(mesh.nC) * sigma_halfspace
blk_ind = utils.ModelBuilder.getIndicesBlock(np.r_[-40, -40, -160],
np.r_[40, 40,
-80], mesh.gridCC)
sigma[mesh.gridCC[:, 2] > 0.0] = 1e-8
sigma[blk_ind] = sigma_block
xmin, xmax = -200.0, 200.0
ymin, ymax = -200.0, 200.0
x = mesh.vectorCCx[np.logical_and(mesh.vectorCCx > xmin,
mesh.vectorCCx < xmax)]
y = mesh.vectorCCy[np.logical_and(mesh.vectorCCy > ymin,
mesh.vectorCCy < ymax)]
xyz = utils.ndgrid(x, y, np.r_[-1.0])
px = np.r_[-200.0, 200.0]
py = np.r_[0.0, 0.0]
pz = np.r_[0.0, 0.0]
srcLoc = np.c_[px, py, pz]
from scipy.interpolate import interp1d
times = np.logspace(-4, -2, 21)
rx_ex = tdem.receivers.PointElectricField(xyz, times + t0, orientation="x")
rx_ey = tdem.receivers.PointElectricField(xyz, times + t0, orientation="y")
rx_by = tdem.receivers.PointElectricField(xyz, times + t0, orientation="y")
rxList = [rx_ex, rx_ey, rx_by]
src = tdem.sources.LineCurrent(rxList, loc=srcLoc, waveform=waveform)
survey = tdem.survey.Survey([src])
sim = tdem.simulation.Simulation3DMagneticFluxDensity(mesh,
survey=survey,
sigma=sigma,
verbose=True)
sim.Solver = Pardiso
sim.solverOpts = {"is_symmetric": False}
sim.time_steps = [(1e-3, 10), (2e-5, 10), (1e-4, 10), (5e-4, 10),
(1e-3, 10)]
t0 = 0.01 + 1e-4
out = waveform_utils.VTEMFun(sim.times, 0.01, t0, 200)
wavefun = interp1d(sim.times, out)
waveform = tdem.sources.RawWaveform(offTime=t0, waveFct=wavefun)
input_currents = wavefun(sim.times)
f = sim.fields(sigma)
xyzlim = np.array([[xmin, xmax], [ymin, ymax], [-400, 0.0]])
actinds, meshCore = utils.ExtractCoreMesh(xyzlim, mesh)
Pex = mesh.getInterpolationMat(meshCore.gridCC, locType="Ex")
Pey = mesh.getInterpolationMat(meshCore.gridCC, locType="Ey")
Pez = mesh.getInterpolationMat(meshCore.gridCC, locType="Ez")
Pfx = mesh.getInterpolationMat(meshCore.gridCC, locType="Fx")
Pfy = mesh.getInterpolationMat(meshCore.gridCC, locType="Fy")
Pfz = mesh.getInterpolationMat(meshCore.gridCC, locType="Fz")
sigma_core = sigma[actinds]
def getEBJcore(src0):
B0 = np.r_[Pfx * f[src0, "b"], Pfy * f[src0, "b"], Pfz * f[src0, "b"]]
E0 = np.r_[Pex * f[src0, "e"], Pey * f[src0, "e"], Pez * f[src0, "e"]]
J0 = utils.sdiag(np.r_[sigma_core, sigma_core, sigma_core]) * E0
return E0, B0, J0
E, B, J = getEBJcore(src)
tdem_gs = {
"E": E,
"B": B,
"J": J,
"sigma": sigma_core,
"mesh": meshCore.serialize(),
"time": sim.times - t0,
"input_currents": input_currents,
}
dd.io.save(fname, tdem_gs)
def run_simulation(fname="tdem_vmd.h5", sigma_halfspace=0.01, src_type="VMD"):
from SimPEG.electromagnetics import time_domain
from scipy.constants import mu_0
import numpy as np
from SimPEG import maps
from pymatsolver import Pardiso
cs = 20.0
ncx, ncy, ncz = 5, 3, 4
npad = 10
npadz = 10
pad_rate = 1.3
hx = [(cs, npad, -pad_rate), (cs, ncx), (cs, npad, pad_rate)]
hy = [(cs, npad, -pad_rate), (cs, ncy), (cs, npad, pad_rate)]
hz = utils.meshTensor([(cs, npadz, -1.3), (cs / 2.0, ncz), (cs, 5, 2)])
mesh = TensorMesh([hx, hy, hz],
x0=["C", "C", -hz[:int(npadz + ncz / 2)].sum()])
sigma = np.ones(mesh.nC) * sigma_halfspace
sigma[mesh.gridCC[:, 2] > 0.0] = 1e-8
xmin, xmax = -600.0, 600.0
ymin, ymax = -600.0, 600.0
zmin, zmax = -600, 100.0
times = np.logspace(-5, -2, 21)
rxList = time_domain.receivers.PointMagneticFluxTimeDerivative(
np.r_[10.0, 0.0, 30.0], times, orientation="z")
if src_type == "VMD":
src = time_domain.sources.CircularLoop(
[rxList],
loc=np.r_[0.0, 0.0, 30.0],
orientation="Z",
waveform=time_domain.sources.StepOffWaveform(),
radius=13.0,
)
elif src_type == "HMD":
src = time_domain.sources.MagDipole(
[rxList],
loc=np.r_[0.0, 0.0, 30.0],
orientation="X",
waveform=time_domain.sources.StepOffWaveform(),
)
SrcList = [src]
survey = time_domain.Survey(SrcList)
sig = 1e-2
sigma = np.ones(mesh.nC) * sig
sigma[mesh.gridCC[:, 2] > 0] = 1e-8
prb = time_domain.Simulation3DMagneticFluxDensity(
mesh,
sigmaMap=maps.IdentityMap(mesh),
verbose=True,
survey=survey,
solver=Pardiso,
)
prb.time_steps = [
(1e-06, 5),
(5e-06, 5),
(1e-05, 10),
(5e-05, 10),
(1e-4, 15),
(5e-4, 16),
]
f = prb.fields(sigma)
xyzlim = np.array([[xmin, xmax], [ymin, ymax], [zmin, zmax]])
actinds, meshCore = utils.ExtractCoreMesh(xyzlim, mesh)
Pex = mesh.getInterpolationMat(meshCore.gridCC, locType="Ex")
Pey = mesh.getInterpolationMat(meshCore.gridCC, locType="Ey")
Pez = mesh.getInterpolationMat(meshCore.gridCC, locType="Ez")
Pfx = mesh.getInterpolationMat(meshCore.gridCC, locType="Fx")
Pfy = mesh.getInterpolationMat(meshCore.gridCC, locType="Fy")
Pfz = mesh.getInterpolationMat(meshCore.gridCC, locType="Fz")
sigma_core = sigma[actinds]
def getEBJcore(src0):
B0 = np.r_[Pfx * f[src0, "b"], Pfy * f[src0, "b"], Pfz * f[src0, "b"]]
E0 = np.r_[Pex * f[src0, "e"], Pey * f[src0, "e"], Pez * f[src0, "e"]]
J0 = utils.sdiag(np.r_[sigma_core, sigma_core, sigma_core]) * E0
return E0, B0, J0
E, B, J = getEBJcore(src)
tdem_is = {
"E": E,
"B": B,
"J": J,
"sigma": sigma_core,
"mesh": meshCore.serialize(),
"time": prb.times,
}
dd.io.save(fname, tdem_is)
